Multi-taxon inventory reveals highly consistent biodiversity responses to ecospace variation

Ane Kirstine Brunbjerg; Hans Henrik Bruun; Lars Dalby; Aimee Taylor Classen; Camilla Fløjgaard; Tobias Guldberg Frøslev; Oskar Liset Pryds Hansen; Toke Thomas Høye; Jesper Erenskjold Moeslund; J.-C. Svenning; Rasmus Ejrnæs

doi:10.1111/oik.07145

Multi-taxon inventory reveals highly consistent biodiversity responses to ecospace variation

Ane Kirstine Brunbjerg^*, Hans Henrik Bruun, Lars Dalby, Aimee Taylor Classen, Camilla Fløjgaard, Tobias Guldberg Frøslev, Oskar Liset Pryds Hansen, Toke Thomas Høye, Jesper Erenskjold Moeslund, J.-C. Svenning, Rasmus Ejrnæs

^*Corresponding author for this work

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

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Abstract

Amidst the global biodiversity crisis, identifying drivers of biodiversity variation remains a key challenge. Scientific consensus is limited to a few macroecological rules, such as species richness increasing with area, which provide limited guidance for conservation. In fact, few agreed ecological principles apply at the scale of sites or reserve management, partly because most community-level studies are restricted to single habitat types and species groups. We used the recently proposed ecospace framework and a comprehensive data set for aggregating environmental variation to predict multi-taxon diversity. We studied richness of plants, fungi, and arthropods in 130 sites representing the major terrestrial habitat types in Denmark. We found the abiotic environment (ecospace position) to be pivotal for the richness of primary producers (vascular plants, mosses, and lichens) and, more surprisingly, little support for ecospace continuity as a driver. A peak in richness at intermediate productivity adds new empirical evidence to a long-standing debate over biodiversity responses to productivity. Finally, we discovered a dominant and positive response of fungi and insect richness to organic matter accumulation and diversification (ecospace expansion). Two simple models of producer and consumer richness accounted for 77 % of the variation in multi-taxon species richness suggesting a significant potential for generalization beyond individual species responses. Our study widens the traditional conservation focus on vegetation and vertebrate populations unravelling the importance of diversification of carbon resources for diverse heterotrophs, such as fungi and insects.

Original language	English
Journal	Oikos
Volume	129
Issue	9
Pages (from-to)	1381-1392
Number of pages	12
ISSN	0030-1299
DOIs	https://doi.org/10.1111/oik.07145
Publication status	Published - 1 Sept 2020

Keywords

abiotic environment
carbon resources
environmental DNA
heterotrophs
primary producers
taxonomic aggregation

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10.1111/oik.07145Licence: CC BY

oik.07145Final published version, 860 KBLicence: CC BY

Cite this

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title = "Multi-taxon inventory reveals highly consistent biodiversity responses to ecospace variation",

abstract = "Amidst the global biodiversity crisis, identifying drivers of biodiversity variation remains a key challenge. Scientific consensus is limited to a few macroecological rules, such as species richness increasing with area, which provide limited guidance for conservation. In fact, few agreed ecological principles apply at the scale of sites or reserve management, partly because most community-level studies are restricted to single habitat types and species groups. We used the recently proposed ecospace framework and a comprehensive data set for aggregating environmental variation to predict multi-taxon diversity. We studied richness of plants, fungi, and arthropods in 130 sites representing the major terrestrial habitat types in Denmark. We found the abiotic environment (ecospace position) to be pivotal for the richness of primary producers (vascular plants, mosses, and lichens) and, more surprisingly, little support for ecospace continuity as a driver. A peak in richness at intermediate productivity adds new empirical evidence to a long-standing debate over biodiversity responses to productivity. Finally, we discovered a dominant and positive response of fungi and insect richness to organic matter accumulation and diversification (ecospace expansion). Two simple models of producer and consumer richness accounted for 77 % of the variation in multi-taxon species richness suggesting a significant potential for generalization beyond individual species responses. Our study widens the traditional conservation focus on vegetation and vertebrate populations unravelling the importance of diversification of carbon resources for diverse heterotrophs, such as fungi and insects.",

keywords = "abiotic environment, carbon resources, environmental DNA, heterotrophs, primary producers, taxonomic aggregation",

author = "Brunbjerg, {Ane Kirstine} and Bruun, {Hans Henrik} and Lars Dalby and Classen, {Aimee Taylor} and Camilla Fl{\o}jgaard and Fr{\o}slev, {Tobias Guldberg} and Hansen, {Oskar Liset Pryds} and H{\o}ye, {Toke Thomas} and Moeslund, {Jesper Erenskjold} and J.-C. Svenning and Rasmus Ejrn{\ae}s",

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doi = "10.1111/oik.07145",

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AU - Brunbjerg, Ane Kirstine

AU - Bruun, Hans Henrik

AU - Dalby, Lars

AU - Classen, Aimee Taylor

AU - Fløjgaard, Camilla

AU - Frøslev, Tobias Guldberg

AU - Hansen, Oskar Liset Pryds

AU - Høye, Toke Thomas

AU - Moeslund, Jesper Erenskjold

AU - Svenning, J.-C.

AU - Ejrnæs, Rasmus

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N2 - Amidst the global biodiversity crisis, identifying drivers of biodiversity variation remains a key challenge. Scientific consensus is limited to a few macroecological rules, such as species richness increasing with area, which provide limited guidance for conservation. In fact, few agreed ecological principles apply at the scale of sites or reserve management, partly because most community-level studies are restricted to single habitat types and species groups. We used the recently proposed ecospace framework and a comprehensive data set for aggregating environmental variation to predict multi-taxon diversity. We studied richness of plants, fungi, and arthropods in 130 sites representing the major terrestrial habitat types in Denmark. We found the abiotic environment (ecospace position) to be pivotal for the richness of primary producers (vascular plants, mosses, and lichens) and, more surprisingly, little support for ecospace continuity as a driver. A peak in richness at intermediate productivity adds new empirical evidence to a long-standing debate over biodiversity responses to productivity. Finally, we discovered a dominant and positive response of fungi and insect richness to organic matter accumulation and diversification (ecospace expansion). Two simple models of producer and consumer richness accounted for 77 % of the variation in multi-taxon species richness suggesting a significant potential for generalization beyond individual species responses. Our study widens the traditional conservation focus on vegetation and vertebrate populations unravelling the importance of diversification of carbon resources for diverse heterotrophs, such as fungi and insects.

AB - Amidst the global biodiversity crisis, identifying drivers of biodiversity variation remains a key challenge. Scientific consensus is limited to a few macroecological rules, such as species richness increasing with area, which provide limited guidance for conservation. In fact, few agreed ecological principles apply at the scale of sites or reserve management, partly because most community-level studies are restricted to single habitat types and species groups. We used the recently proposed ecospace framework and a comprehensive data set for aggregating environmental variation to predict multi-taxon diversity. We studied richness of plants, fungi, and arthropods in 130 sites representing the major terrestrial habitat types in Denmark. We found the abiotic environment (ecospace position) to be pivotal for the richness of primary producers (vascular plants, mosses, and lichens) and, more surprisingly, little support for ecospace continuity as a driver. A peak in richness at intermediate productivity adds new empirical evidence to a long-standing debate over biodiversity responses to productivity. Finally, we discovered a dominant and positive response of fungi and insect richness to organic matter accumulation and diversification (ecospace expansion). Two simple models of producer and consumer richness accounted for 77 % of the variation in multi-taxon species richness suggesting a significant potential for generalization beyond individual species responses. Our study widens the traditional conservation focus on vegetation and vertebrate populations unravelling the importance of diversification of carbon resources for diverse heterotrophs, such as fungi and insects.

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KW - carbon resources

KW - environmental DNA

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JO - Oikos

JF - Oikos

IS - 9

ER -

Multi-taxon inventory reveals highly consistent biodiversity responses to ecospace variation

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BIOWIDE: Biodiversity in width and depth

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Multi-taxon inventory reveals highly consistent biodiversity responses to ecospace variation

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BIOWIDE: Biodiversity in width and depth

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